US5808969A - Method and device for detecting objects dispersed in an area of land - Google Patents

Method and device for detecting objects dispersed in an area of land Download PDF

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US5808969A
US5808969A US08/566,713 US56671395A US5808969A US 5808969 A US5808969 A US 5808969A US 56671395 A US56671395 A US 56671395A US 5808969 A US5808969 A US 5808969A
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transducers
ground
area
signal
determining
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Philippe Arnaud
Loic Laine
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Giat Industries SA
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Giat Industries SA
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F41WEAPONS
    • F41HARMOUR; ARMOURED TURRETS; ARMOURED OR ARMED VEHICLES; MEANS OF ATTACK OR DEFENCE, e.g. CAMOUFLAGE, IN GENERAL
    • F41H11/00Defence installations; Defence devices
    • F41H11/12Means for clearing land minefields; Systems specially adapted for detection of landmines
    • F41H11/16Self-propelled mine-clearing vehicles; Mine-clearing devices attachable to vehicles

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  • the scope of the present invention is that of processes and devices allowing the detection of objects, and in particular the detection of mines dispersed over an area of land.
  • Mine detection processes and devices which use magnetic means. These devices implement a generator and a conductive coil. When a conductive material is found in the vicinity of the coil, the current flowing through the latter is disturbed and a detection signal is supplied by a processing electric circuit.
  • Such detection devices oblige the detection coil to be brought into the vicinity of the mine, thereby endangering the person responsible for handling the detector and thus making demining operations both long and difficult.
  • the detector risks being activated by magnetic objects other than the mines being searched for thereby causing false alarms which slow down the demining operations even more.
  • a detection process and device are known elsewhere, notably by patent FR2696573, which are based on the principle of the temporal reversal of an acoustic wave.
  • This process implements a certain number of acoustic transducers (emitters/receivers) which enables an acoustic beam to be aimed, practically automatically, at an object whose exact location is unknown.
  • the analysis of the signals picked up after a certain number of iterations enables a wave front to be determined wherein the crest or focal point indicates the location of the object.
  • Such a process is particularly well-adapted to medical imagery and enables the exact location of stones or tumours in the human body to be determined.
  • the transducers are placed at relatively small distances from the objects to be detected (less than 200 mm) and the propagation speed of the sound waves remains roughly the same in every direction of the area to be explored.
  • This process is, however, ill-adapted to the detection of objects in the ground and notably in land of a large surface area (in the region of 5 to 10,000 m 2 ).
  • the aim of the present invention is to propose a detection process which does not present such disadvantages.
  • the process according to the invention thus enables the detection using acoustic means of objects (in particular mines) dispersed over an area of land. Therefore, it is not affected by the type of material, magnetic or not, which make up the objects.
  • the process according to the invention may be implemented at a distance from the objects to be detected thereby improving the safety of the operation when the objects in question are mines.
  • the process according to the invention enables objects to be detected in an area of land which is very large without having to go over the land with detection means, thereby improving safety even more.
  • the process according to the invention also allows, when being used for mine detection, the activation or destruction of the mines by remote control.
  • the subject of the invention is thus a process to detect objects, and in particular mines dispersed over an area of land, a process characterised in that it implements a multiplicity of acoustic transducers and in that the following stages are carried out:
  • an optimal operational frequency is firstly determined for the transducers in accordance with the type of ground, a frequency which gives a received signal amplitude which is at its maximum for the majority of the transducers when emitted by one of them;
  • a brief and unfocused initial pulse is sent into the ground by at least one transducer at this optimal frequency;
  • each echo signal being memorized according to time, the start time being the instant of sending the initial pulse;
  • the echo signals coming from a first object located in the area of land are selected;
  • the location direction is determined in which the first object lies, a direction defined as the mean perpendicular of the segment joining two transducers for which the propagation time is roughly the same.
  • a position is determined for the first object along its location direction by calculating the distances travelled by the reflected waves received by the transducers which define the location direction.
  • the acoustic transducers are arranged along at least two converging lines and in that the location of the first object is determined as being the intersection point or area of at least two location directions.
  • the first object to processed by temporal reversal is chosen by analysing the wave shapes according to the different return echos received by each transducer followed by the comparison of these wave shapes against a library of the characteristic signatures of the main objects to be detected.
  • the first object is identified after carrying out the k temporal reversals by analyzing the wave shapes according to the different echo signals received by each transducer and comparing these wave shapes with a library of characteristic signatures of the main objects to be detected.
  • At least one other acoustic signal is emitted to the latter having the shape of that memorized after the last temporal reversal, an amplified signal of sufficient intensity to make the object move or vibrate.
  • a further subject of the invention is also a device to detect objects, and in particular mines dispersed in an area of land, a device which implements such a process and which is characterized in that it comprises at least one row of acoustic transducers connected to processing electronics, each transducer being carried by a support designed to be buried in or applied on the ground.
  • the detection device can comprise at least one row of aligned supports or at least two rows of supports arranged along converging lines.
  • the supports can be integral with at least one ramp carried by at least one vehicle, a ramp whose position can be adjusted in order to allow the supports to be positioned with respect to the ground.
  • Each row of supports can be carried by a different vehicle.
  • the supports can be installed individually on the land, a radio link being provided in that case between each support and at least one part of the processing electronics so as to allow the synchronization of pulses emitted by the transducers.
  • FIG. 1 shows in diagram form an area of land dispersed with objects to be detected and in the vicinity of which a detection device according to the invention has been placed;
  • FIG. 2 shows such an area of land on which a detection device according to a second embodiment of the invention has been placed
  • FIG. 3 is a flow chart of the processing electronics corresponding to the device according to the invention.
  • FIG. 4a shows a device according to a first embodiment mounted onto a vehicle
  • FIG. 4b shows the ramp used by the vehicle in FIG. 4a on its own
  • FIG. 5 shows in diagram form the implementation of the device according to the invention using two vehicles
  • FIG. 6 shows a device according to another embodiment of the invention.
  • FIG. 7 is a flow chart of the electronics corresponding to another embodiment of the invention.
  • an area of land marked out here by dotted lines, contains a certain number of objects 2, which are buried mines.
  • a detection device 3 according to a first embodiment of the invention comprises a certain number of acoustic transducers distributed along a line 5 (the different transducers are numbered 4.1, 4.2, . . . 4.i, 4.n).
  • the transducers are constituted in a conventional manner by piezoelectrical ceramic plates or by electromagnetic transducers.
  • the transducers will be separated from one another by a distance of 200 mm to 1 m. Spacing will advantageously be chosen such that the value is around the same as the largest size of the mines or objects to be detected.
  • the transducers are arranged so as to be able to emit and receive acoustic waves in the ground. They are carried, for example, on supports in the shape of pegs which enable them to be installed at an optimal depth (for example, the usual depth at which mines are laid, i.e. from 200 to 300 mm).
  • the transducers could also be carried on supports which are merely placed on the ground. In this event, the support ensures that the transducer remains flat against the ground.
  • the acoustic waves are therefore emitted on the surface but they propagate, nevertheless, through a layer of ground which is around 200 to 300 mm in depth, thereby enabling the detection of mines which are usually buried at such depths.
  • the transducers 4.1 to 4.n are connected to an electronic processing box 6 which comprises a certain number of bands 7.1, 7.2, . . . 7.i, 7.n (one band per transducer) and a common control unit 8.
  • an optimal operational frequency for the transducers will first of all be determined.
  • This frequency depends on the type of ground in which the mines are placed.
  • an unfocused frequency will be applied (for example, by means of a wobbling frequency generator) to a single transducer, preferably the one positioned in the middle of the line 5, and the signals received by the other transducers will be analyzed according to the frequency emitted.
  • a working frequency will be retained for which the amplitude of the signals received by the transducers is at its maximum for the majority of the transducers (at least 50% of them).
  • the operational frequencies mostly vary between 10 Hz and 100 kHz according to the type of ground.
  • a brief and unfocused pulse at this frequency is sent into the ground of the area of land in question by at least one transducer.
  • the method consists in:
  • the number of temporal reversals depends on the type of ground, an odd number of temporal reversals may be preferred so as to have a symmetrical wave front from the signals obtained.
  • the focusing obtained is sufficient when the echo returned from a target stands out clearly from the others, for example, when its amplitude is at least three times greater than that of the others.
  • the wave front received from the ground doesn't have an even enough curve to be able to determine a center or focal position for the mine.
  • transducers are located for which the measured propagation times are roughly the same.
  • Transducers fulfilling this condition which are next to each other on line 5 will advantageously be chosen. Such a choice enables locating accuracy to be improved. Indeed, when the transducers are near to one another, the propagation speeds in the ground are roughly the same for the signals received by these two transducers.
  • a direction D is determined, called the location direction, along which, in theory, the first mine is to be located.
  • This direction is defined as the mean perpendicular of a segment joining two transducers for which the propagation times are roughly equal.
  • Each propagation time is measured by the control unit 8 as the time gap which separates, for any given transducer, the outward signal and the echo return corresponding to the mine.
  • a location direction D has been illustrated which corresponds to the mean perpendicular between transducers 4.(n-1) and 4.n.
  • the mine is not obligatorily along direction D but it may be found in a band 9 (hatched) which is perpendicular to the distribution line 5 of the transducers. This band is centered on direction D and its width is equal to double the distance which separates the transducers.
  • the mine will be considered to be along direction D and/or in the band 9 and at a distance from line 5 which is determined as half the ratio of the propagation speed of the sound wave in the ground to the propagation time.
  • the propagation speed in the ground will be assessed by a specific measurement. For example, a measurement made at the first stage during the determination of the optimum working frequency. In fact, during this stage it is easy to make the different ratios between the distances between the emitting transducer and each receiving transducer and the propagation times measured.
  • the propagation speed thus assessed may be chosen as a mean value of the different propagation speeds measured.
  • the position of the mine along direction D can also be determined by calculating the intersection point of the circles centered on each of the two transducers in question, circles whose diameters will be calculated as equal to the ratio of the propagation speed of the sound wave in the ground to the propagation time measured for the transducer in question.
  • the temporal window is chosen from the first echo signal received by the device.
  • those signals surrounding certain maximums noted on the echos are returned, the maximums theoretically corresponding to a wave reflected by an object.
  • the objects nearest to the transducers will firstly be examined, the temporal window will therefore ignore the echos coming from more remote objects.
  • the wave shapes which follow the different return echos received by each transducer may advantageously be analyzed and compared with a library of characteristic signatures of the main types of mine to be detected.
  • Such a library is easy to set up by carrying out the calibration of the device on a terrain which is known and in which are buried one after the other the different known types of mine which may have to be detected.
  • the comparison of the wave shapes with those of the signature library will preferably be carried out by means of neuronal circuits. Such circuits are known to the expert and they allow the rapid calculation of shape recognition.
  • the advantage of employing the iterative process of signal temporal reversals enables the signal to be focused on one mine in particular. Parasite signals are thus eliminated and location accuracy by the transducers is improved. It becomes easy to isolate at least two contiguous transducers for which the propagation time is roughly equal.
  • FIG. 3 shows an embodiment of an electronic processing box 6 enabling the above process to be implemented.
  • This processing electronics comprises the processing bands 7.1, . . . , 7.i, . . . , 7.n and a common control unit 8.
  • Each transducer 4.1 is associated with one processing band 7.i (only one band is shown here).
  • Each band 7.i comprises a sampler 10 which is designed to supply analog samples of the signal received by the transducer 4.i at the frequency of a clock 11 of the control unit 8.
  • the sampling frequency given by the clock will depend on the optimal working frequency. It will preferably be above R/dxV, expression in which R is the resolution or the number of points of the signal (100, for example), d is the main dimension of the smallest object to be detected and V the mean propagation speed of the waves in the ground.
  • the time lapses during which the sampler works are determined by a rate setter 12 (also integral with the control unit 8).
  • the rate setter enables a temporal window to be defined in which the echo signals will be examined by the different samplers.
  • the duration of the temporal window will be chosen long enough so that each transducer can receive a return echo corresponding to the mine.
  • this temporal window is determined after receiving the first echo signals, in such a way as to encompass and the required maximums which correspond to the first mine.
  • the temporal window or windows will be chosen by the user by acting on the rate setter 12 by means of a computer 13 (also integral with the control unit 8) which is fitted with a suitable interface for the user (keyboard, screen, etc).
  • the sampler 10 is followed by an analog/digital converter 14.
  • an analog/digital converter 14 As a general rule, a conversion over ten bits is enough to show the echos in a satisfactory manner.
  • the words which are representative of a sample are stored in a memory bank 15, organized in the form of a stack (of the last in--first out type).
  • This memory bank will be chosen big enough to store all the samples received during the duration of the temporal window.
  • the rate setter 12 is also provided to cause the emission of a wave front returned after a brief period of time after receiving the received echo (a few milliseconds).
  • Each band 7.i comprises a digital/analog converter 16 to enable re-emission, possibly followed by an amplifier 17 whose output drives the associated transducer 4.i.
  • An exciting circuit 20 enables a brief and unfocused initial pulse to be applied to one or several transducers at the optimal frequency.
  • This exciting circuit can also be used to determine tho optimal working frequency.
  • the circuit 20 is shown connected to all the transducers. In fact, means (not shown) are provided to connect it to one or several transducers at the user's discretion.
  • the computer 13 will be connected to all the bands 7.i associated with the different transducers. The same applies to the clock 11 and the rate setter 12. The synchronization of all the different bands being essential to the service quality of the focusing device by temporal reversal of the echos.
  • the connections joining the control unit 8 to the different processing bands 7.i is shown in reference 34.
  • the computer 13 compares the signals received against the mine library and it will therefore comprise the memory banks containing the signature library as well as the required neuronal circuits.
  • the computer 13 also determines (after carrying out the temporal reversals) the transducers having the same return times. It defines thereafter the location direction and/or the location band.
  • a display monitor can facilitate the utilization of the data by the user (visualization of directions and/or bands as well as the theoretical location of the mines).
  • Determining this laying pattern will help to increase the detection speed for the other mines by allowing the quick definition of the temporal windows which correspond to areas of land in which a mine may theoretically be found if the mesh is exact.
  • FIG. 2 shows an area of land 1 which contains a certain number of mines 2 which are buried.
  • the detection device 3 comprises acoustic transducers which are distributed along two converging lines 5a and 5b.
  • the transducers are numbered in the following manner:
  • Each line of transducers is controlled by a specific electronic processing box 6a, 6b.
  • Each box 6a and 6b comprises, as above, processing bands (7.1a, . . . 7.ia, . . . 7.na and 7.1b, . . . 7.ib, . . . 7.nb) as well as a common control unit 8a or 8b.
  • the processing boxes 6a and 6b are connected to a common command module 19.
  • the command module 19 will firstly command the focusing by temporal reversal of the transducers in line 5a on a first mine. This first stage will lead to the definition of a location direction Da, defined as the mean perpendicular of the segment joining two transducers (preferably contiguous) and for which the signal propagation times are roughly equal.
  • FIG. 2 the location direction Da which corresponds to the mean perpendicular between transducers 4.(n-1)a and 4.na is shown.
  • the command module 19 will command the focusing by temporal reversal of the transducers of the second line 5b on the same first mine.
  • a suitable temporal window will be chosen so as to be sure that focusing will effectively occur for the same mine. This choice will be made by means of an assessment of the actual distance between the first location direction Da and line 5b.
  • the actual positions of the lines will be known by suitable means, associating, for example, inertial platforms, GPS (positioning in space by satellite) systems, range finders.
  • transducers will be searched for on line 5b for which the signal propagation times are roughly equal, which will lead to the definition of a location direction Db, defined as the mean perpendicular of the segment joining these two transducers.
  • FIG. 2 the location direction Db which corresponds to the mean perpendicular between transducers 4.1b and 4.2b is shown.
  • the mine is not obligatorily to be found at the intersection of direction Da and Db but is located in a zone Z which is the intersection of the bands 9.a and 9.b (hatched).
  • Each band is parallel to the direction Da or Db under consideration and is centered on the latter.
  • the width of each band is equal to or double the distance separating the two transducers.
  • control unit 8 common to both lines of transducers can be, advantageously, selected for use, this part of the processing electronics will therefore be included in the command module 19.
  • a common computer will thus determine the different location directions and/or bands and will compute the locations of the different mines as being at the intersection of these directions and/or bands.
  • connections between boxes 6a, 6b and the command module 19 could either be in wire form or could be made by radio or optical means.
  • FIG. 4a shows a tracked vehicle 21 which carries a ramp 22 on which supports 23.1,23.2, . . . 23.n, are fastened, in this example the supports are in the form of pegs.
  • This ramp is shown on its own in FIG. 4b.
  • Each peg 23.i carries a transducer 4.i. The pegs enable all the transducers to be positioned at the same depth in the ground.
  • the position of the ramp, and thus the position of the pegs in the ground, can be adjusted by means of a first jack 24 (hydraulic or electric) which enables the slope of the ramp support brackets 25 to be adjusted with respect to the vehicle 21.
  • This first jack is mounted between the vehicle and a race 26 integral with the bracket 25.
  • a second jack 27 is positioned between the brace 26 and the ramp 22. It enables the ramp to be pivoted with respect to the brackets 22 and thus the penetration angle of the pegs 23 in the ground. Sensors, not shown, enable the position of the pegs with respect to the ground (angle and penetration depth) to be measured.
  • the vehicle 21 carries the processing box 6 will maybe be connected by radio to a command module which, in that event, will contain part of the processing electronics.
  • the pegs can be replaced by supports which are not pushed into the ground but which enable the transducers to be positioned in contact with the ground.
  • FIG. 5 shows the implementation in diagram form of the device according to the invention using two vehicles 21a and 21b.
  • Vehicle 21a is fitted with a ramp 22a on which the supports, such as pegs, carrying the transducers are fastened.
  • Vehicle 21b is fitted with a ramp upon which supports carrying transducers are also fastened.
  • the ramp 22a is arranged laterally with respect to the vehicle 21b (with a suitable assembly of brackets and jacks) and this in order to facilitate the advance of the vehicle along a direction A with a minimal number of maneuvers. It would naturally be possible to use an identical ramp assembly on both vehicles. The repositioning of each vehicle will be made easier by their being fitted with location means (inertial unit, GPS system).
  • Pi vehicle 21a After processing all the parts Pi vehicle 21a will be moved along direction B in order to explore another part of the area 1.
  • the operations will be coordinated by the command module 19 which will preferably be connected by radio to each vehicle.
  • FIGS. 6 and 7 show a device according to another embodiment of the invention.
  • the transducers are once again carried by supports in the form of pegs 23, but each peg is individually set into position on the area of land 1.
  • This area of land 1 has been surrounded by pegs 23 which are distributed along two converging lines.
  • This embodiment of the invention also implements the process described with reference to FIG. 2.
  • the spacing of the different pegs was accurately measured when they were set into position.
  • Each peg 23.ia or 23.ib is fitted with a box 28.ia or 28.ib which contains the processing band 7.i associated with the transducer 4.i fitted onto the peg (refer also to FIG. 7).
  • the box 28.i also contains a radio emitter/receiver 29.i and is fitted with an antenna 30.I.
  • the command module 19 is placed at a distance from the area of land 1. It also contains a radio emitter/receiver 31 coupled with an antenna 32.
  • the command module contains part of the processing electronics. It ensures the operation of the common control unit 8 described above with reference to FIG. 3. It therefore contains a clock 11, a rate setter 12 and a computer 13.
  • the use of a common clock and rate setter as well as a radio link makes it possible to synchronize the emissions from the different transducers, even for a large number of the latter and over large distances.
  • a decoder 33 enables the radio data sent by the different pegs to be transformed into data able to be utilized by the computer.
  • the command module 19 will firstly carry out focusing by temporal reversal from a first line of transducers 5a and will then carry out a separate focusing from the second line of transducers 5b.
  • This embodiment of the invention enables large surface areas of land (over 10 m ⁇ 10 m) to be processed in a single operation. However, the set up is longer, this embodiment is therefore better adapted to clean-up operations of battle zones after combat.
  • a last signal, temporally returned, will be projected onto it but whose amplitude will be substantially amplified by means of a suitable power generator (for example, in a ratio of 1,000 to 100,000 according to the type, hard or soft, of the ground).
  • the invention has been described within the scope of its use to detect land mines. It is naturally applicable to the detection of sea mines, whether buried or not, or else to the detection of buried objects or to the registering of heterogeneities in the ground.

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  • Physics & Mathematics (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Acoustics & Sound (AREA)
  • Environmental & Geological Engineering (AREA)
  • Geology (AREA)
  • Remote Sensing (AREA)
  • General Life Sciences & Earth Sciences (AREA)
  • General Physics & Mathematics (AREA)
  • Geophysics (AREA)
  • General Engineering & Computer Science (AREA)
  • Geophysics And Detection Of Objects (AREA)
  • Measurement Of Velocity Or Position Using Acoustic Or Ultrasonic Waves (AREA)
US08/566,713 1994-12-20 1995-12-04 Method and device for detecting objects dispersed in an area of land Expired - Fee Related US5808969A (en)

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FR9415337A FR2728354A1 (fr) 1994-12-20 1994-12-20 Procede de detection d'objets repartis dans une zone de terrain et dispositif mettant en oeuvre un tel procede
FR9415337 1994-12-20

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EP (1) EP0718639B1 (ja)
DE (1) DE69512751T2 (ja)
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US5929363A (en) * 1997-04-05 1999-07-27 Rheinmetall W & M Gmbh Method and apparatus for destroying hidden land mines
WO1999051995A2 (en) * 1998-03-17 1999-10-14 Wilk Patent Development Corporation Imaging system for detecting underground and underwater objects and associated method
US5988038A (en) * 1998-01-22 1999-11-23 Raytheon Company Method and apparatus for destroying buried objects
US6055214A (en) * 1998-07-23 2000-04-25 Wilk; Peter J. Imaging system for detecting underground objects and associated method
US6418081B1 (en) 1998-02-10 2002-07-09 The Research Foundation Of State University Of New York System for detection of buried objects
US20030158672A1 (en) * 1999-11-10 2003-08-21 Kalyanaraman Ramnarayan Use of computationally derived protein structures of genetic polymorphisms in pharmacogenomics for drug design and clinical applications
US6678403B1 (en) 2000-09-13 2004-01-13 Peter J. Wilk Method and apparatus for investigating integrity of structural member
US6690617B2 (en) * 2001-05-18 2004-02-10 Gas Research Institute Application of sonic signals to detect buried, underground utilities
US20060141480A1 (en) * 1999-11-10 2006-06-29 Kalyanaraman Ramnarayan Use of computationally derived protein structures of genetic polymorphisms in pharmacogenomics and clinical applications
US7804741B1 (en) 2009-09-28 2010-09-28 The United States Of America As Represented By The Secretary Of The Navy System and method for focusing a kinetic pulse array
US20150131084A1 (en) * 2013-11-12 2015-05-14 Woods Hole Oceanographic Institution Sensor System for Environmental Impact Monitoring
DE102005001732B4 (de) * 2005-01-14 2015-09-17 Robert Bosch Gmbh Vorrichtung und Verfahren zur Abstandsbestimmung
US20160161451A1 (en) * 2013-11-12 2016-06-09 Woods Hole Oceanographic Institution Turbine Sensor System For Environmental Impact Monitoring

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DE19730571C1 (de) * 1997-07-17 1999-04-22 Diehl Stiftung & Co Minensuchnadel
AU9621198A (en) * 1997-10-15 1999-05-03 Minedetektor Aps A mine detector and a method for detecting mines
DE102011050006A1 (de) * 2011-04-29 2012-10-31 Aesculap Ag Instrumenten-Identifikationsvorrichtung

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FR2728354A1 (fr) 1996-06-21
DE69512751T2 (de) 2000-03-02
NO955164D0 (no) 1995-12-19
EP0718639B1 (fr) 1999-10-13
NO955164L (no) 1996-06-21
FR2728354B1 (ja) 1997-02-21
DE69512751D1 (de) 1999-11-18
EP0718639A1 (fr) 1996-06-26

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